@Preamble{"\def\germ{\frak} \def\scr{\cal}
 \ifx\documentclass\undefinedcs
      \def\bf{\fam\bffam\tenbf}\def\rm{\fam0\tenrm}\fi
                          % f**k-amstex!
 \def\defaultdefine#1#2{\expandafter\ifx\csname#1\endcsname\relax
 \expandafter\def\csname#1\endcsname{#2}\fi}
 \defaultdefine{Bbb}{\bf}   \defaultdefine{frak}{\bf}
  \defaultdefine{=}{\B}   % doublef**k-amstex!!
  \defaultdefine{mathfrak}{\frak}
       \defaultdefine{mathbb}{\bf}
       \defaultdefine{mathcal}{\cal}
      \defaultdefine{beth}{BETH}\defaultdefine{cal}{\bf}
     \def\bbfI{{\Bbb I}}   \def\mbox{\hbox}  \def\text{\hbox}
   \def\om{\omega}    \def\Cal#1{{\bf #1}} \def\pcf{pcf}
        \defaultdefine{cf}{cf}
    \defaultdefine{reals}{{\Bbb R}} \defaultdefine{real}{{\Bbb R}}
   \def\restriction{{|}}  \def\club{CLUB}
   \def\w{\omega} \def\exist{\exists}
   \def\se{{\germ se}}     \def\bb{{\bf b}}
   \def\equivalence{\equiv}
   \let\lt<  \let\gt>
           "}

@MISC{GeForceGTX680,
    title = {GeForce GTX 680},
    howpublished = "\url{http://www.geforce.com/hardware/desktop-gpus/geforce-gtx-680}",
}

@MISC{waterissues,
    author = {Jeffrey W. Jacobs},
    howpublished = "\url{http://www.waterencyclopedia.com/Da-En/Developing-Countries-Issues-in.html}",
}

@MISC{nvprof,
    author = {NVDIA},
    howpublished = "\url{http://docs.nvidia.com/cuda/profiler-users-guide/#axzz3aPF6qywC}",
}

@article {cyber_physical_systems,
    author = {Teodora Sanislav, Liviu Miclea},
    title = {Cyber-Physical Systems - Concept.},
    journal = {Challenges and Research Areas. CEAI, Vol.14, No.2,},
    pages = {28--33},
    year = {2012}
}

@article {RobertMItami,
   author = {Robert M. Itami.},
   title = {Simulating spatial dynamics: cellular automata theory.},
   journal = {Landscape and Urban Planning 30.},
   pages = {27--47},
   keywords = {Cellular automata theory, Enviromental modeling, GIS},
   year = {1994}
}

@article {NetGenDoc,
    author = {Bernard Pottier, Pierre-Yves Lucas.},
    title = {Dynamic networks – NetGen: objectives, installation, use, and programming.},
    journal = {Université de Bretagne Occidentale.},
    year = {2014}
}

@inproceedings{Lee10_CPSFoundations,
    author = {Edward A. Lee},
    title = {CPS Foundations},
    booktitle = {Proc. of the 47th Design Automation Conference (DAC)},
    organization = {ACM},
    pages = {737-742},
    month = {June},
    year = {2010},
    abstract = {This paper argues that cyber-physical systems
              present a substantial intellectual challenge that
              requires changes in both theories of computation
              and dynamical systems theory. The CPS problem is
              not the union of cyber and physical problems, but
              rather their intersection, and as such it demands
              models that embrace both. Two complementary
              approaches are identified: cyberizing the physical
              (CtP) means to endow physical subsystems with
              cyber-like abstractions and interfaces; and
              physicalizing the cyber (PtC) means to endow
              software and network components with abstractions
              and interfaces that represent their dynamics in
              time.},
    URL = {http://chess.eecs.berkeley.edu/pubs/804.html}
}

@article{WirelessSensorNetwork,
    author = {Luís M. L. Oliveira, Joel J. P. C. Rodrigues},
    title = {Wireless Sensor Networks: a Survey on Environmental Monitoring},
    journal = {Journal of Communications},
    volume = {6},
    number = {2},
    month = {April},
    year = {2011},
    abstract = {Traditionally, environmental monitoring is
achieved by a small number of expensive and high precision
sensing unities. Collected data are retrieved directly from
the equipment at the end of the experiment and after the
unit is recovered. The implementation of a wireless sensor
network provides an alternative solution by deploying a
larger number of disposable sensor nodes. Nodes are
equipped with sensors with less precision, however, the
network as a whole provides better spatial resolution of the
area and the users can have access to the data immediately.
This paper surveys a comprehensive review of the available
solutions to support wireless sensor network environmental
monitoring applications.},
    URL = {http://www.jocm.us/uploadfile/2013/0403/20130403030225404.pdf}
}

@article{TrafficPredictionSystem,
    author = {T.Shiraishi, M.Kuwahara,R.Horiguchi},
    title = {A Development of Traffic Prediction System Based on Real-time Simulation},
    journal = {12th World Congress on Intelligent Transport Systems proceedings},   
    month = {November},
    year = {2005},
    abstract = {The purpose of this research is to develop a traffic prediction system by using the real-time 
information (vehicle detector, VICS etc) and the existent traffic simulation. It is to watch 
conditions to change with the time always and to hold traffic control suitably. Recently, a 
traffic jam happens chronically frequently, and it is a big social problem in the urban 
expressway. To control this traffic safely and smoothly, it is important to give a plan more 
rapidly and suitably. We think that this system is useful as an examination and evaluation tool 
of the policy by predicting future short-term traffic conditions from the present traffic 
conditions.},
    URL = {http://www.plan.civil.tohoku.ac.jp/kuwahara/publications/2005-028.pdf}
}
@article {IEEEHLARules,
    author = {},
    title = {IEEE Standard for Modeling and Simulation (M&S) High Level Architecture (HLA)-- Framework and Rules. IEEE Std 1516-2010 (Revision of IEEE Std 1516-2000), pp. 1-38},  
    day = {18},
    	month = {August},
    year = {2010},
    	abstract={This standard, describing the framework and rules of the High Level Architecture (HLA), is the capstone document for a family of related HLA standards. It defines the HLA, its components, and the rules that outline the responsibilities of HLA federates and federations to ensure a consistent implementation. Simulations are abstractions of the real world, and no one simulation can solve all of the functional needs for the modeling and simulation community. It is anticipated that technology advances will allow for new and different modeling and simulation (M&S) implementations within the framework of the HLA. The standards contained in this architecture are interrelated and need to be considred as a product set, as a change in one is likely to have an impact on the others. As such, the HLA is an integrated approach that has been developed to provide a common architecture for simulation.}
}

@MISC{Cirbus_cellularautomata,
    author = {Juraj Cirbus and Michal Podhoranyi},
    title = {Cellular Automata for the Flow Simulations on the Earth Surface, Optimization Computation Process},
    day={1},
    month={November},
    year = {2013},
    abstract={The spreading of water across terrain is not a simple and isolated process. The spread of water is a part of the more general water cycle. Many commercial software exist for water modelling, but their correct use requires a considerable knowledge of water modelling, and about the study area. Using the relatively simple principle of cellular automata (CA) it is possible to obtain results which compare well with real measurements. This article describes using a CA for simulating the spreading of liquid, using comparatively simple rules and conditions which include several factors affecting the spreading of water such as slope, roughness and infiltration. A disadvantage of CA is the slower calculation process, which is strongly dependent on the size of the study area. We address this issue by using three optimization methods to reduce the computation time.}
}
